Your search keyword '"Mengyi Cao"' showing total 4 results

1. Apex Predator Nematodes and Meso-Predator Bacteria Consume Their Basal Insect Prey through Discrete Stages of Chemical Transformations

Author

Nicholas C. Mucci, Katarina A. Jones, Mengyi Cao, Michael R. Wyatt, Shane Foye, Sarah J. Kauffman, Gregory R. Richards, Michela Taufer, Yoshito Chikaraishi, Shawn A. Steffan, Shawn R. Campagna, and Heidi Goodrich-Blair

Subjects

Insecta, Physiology, Tryptophan, Moths, Biochemistry, Microbiology, Xenorhabdus, Computer Science Applications, Rhabditida, Modeling and Simulation, Genetics, Animals, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Ecosystem

Abstract

Microbial symbiosis drives physiological processes of higher-order systems, including the acquisition and consumption of nutrients that support symbiotic partner reproduction. Metabolic analytics provide new avenues to examine how chemical ecology, or the conversion of existing biomass to new forms, changes over a symbiotic life cycle. We applied these approaches to the nematode Steinernema carpocapsae, its mutualist bacterium, Xenorhabdus nematophila, and the insects they infect. The nematode-bacterium pair infects, kills, and reproduces in an insect until nutrients are depleted. To understand the conversion of insect biomass over time into either nematode or bacterium biomass, we integrated information from trophic, metabolomic, and gene regulation analyses. Trophic analysis established bacteria as meso-predators and primary insect consumers. Nematodes hold a trophic position of 4.6, indicative of an apex predator, consuming bacteria and likely other nematodes. Metabolic changes associated with Galleria mellonella insect bioconversion were assessed using multivariate statistical analyses of metabolomics data sets derived from sampling over an infection time course. Statistically significant, discrete phases were detected, indicating the insect chemical environment changes reproducibly during bioconversion. A novel hierarchical clustering method was designed to probe molecular abundance fluctuation patterns over time, revealing distinct metabolite clusters that exhibit similar abundance shifts across the time course. Composite data suggest bacterial tryptophan and nematode kynurenine pathways are coordinated for reciprocal exchange of tryptophan and NAD

Published

2022

2. The entomopathogenic nematode Steinernema hermaphroditum is a self-fertilizing hermaphrodite and a genetically tractable system for the study of parasitic and mutualistic symbiosis

Author

Paul W. Sternberg, Chieh-Hsiang Tan, Mengyi Cao, and Hillel T. Schwartz

Subjects

Investigation, Genetics, Mutualism (biology), biology, Xenorhabdus, Entomopathogenic nematode, biology.organism_classification, medicine.disease_cause, Symbiosis, Xenorhabdus griffiniae, Genetic model, medicine, Photorhabdus, Symbiotic bacteria

Abstract

Entomopathogenic nematodes (EPNs), including Heterorhabditis and Steinernema, are parasitic to insects and contain mutualistically symbiotic bacteria in their intestines (Photorhabdus and Xenorhabdus, respectively) and therefore offer opportunities to study both mutualistic and parasitic symbiosis. The establishment of genetic tools in EPNs has been impeded by limited genetic tractability, inconsistent growth in vitro, variable cryopreservation, and low mating efficiency. We obtained the recently described Steinernema hermaphroditum strain CS34 and optimized its in vitro growth, with a rapid generation time on a lawn of its native symbiotic bacteria Xenorhabdus griffiniae. We developed a simple and efficient cryopreservation method. Previously, S. hermaphroditum isolated from insect hosts was described as producing hermaphrodites in the first generation. We discovered that CS34, when grown in vitro, produced consecutive generations of autonomously reproducing hermaphrodites accompanied by rare males. We performed mutagenesis screens in S. hermaphroditum that produced mutant lines with visible and heritable phenotypes. Genetic analysis of the mutants demonstrated that this species reproduces by self-fertilization rather than parthenogenesis and that its sex is determined chromosomally. Genetic mapping has thus far identified markers on the X chromosome and three of four autosomes. We report that S. hermaphroditum CS34 is the first consistently hermaphroditic EPN and is suitable for genetic model development to study naturally occurring mutualistic symbiosis and insect parasitism.

Published

2021

3. The entomopathogenic nematodeSteinernema hermaphroditumis a self-fertilizing hermaphrodite and a genetically tractable system for the study of parasitic and mutualistic symbiosis

Author

Hillel T. Schwartz, Chieh-Hsiang Tan, Paul W. Sternberg, and Mengyi Cao

Subjects

Genetics, Symbiosis, biology, Xenorhabdus griffiniae, Genetic model, medicine, Xenorhabdus, Entomopathogenic nematode, Mating, biology.organism_classification, medicine.disease_cause, Photorhabdus, Symbiotic bacteria

Abstract

Entomopathogenic nematodes, includingHeterorhabditisandSteinernema, are parasitic to insects and contain mutualistically symbiotic bacteria in their intestines (PhotorhabdusandXenorhabdus,respectively) and therefore offer opportunities to study both mutualistic and parasitic symbiosis. The establishment of genetic tools in entomopathogenic nematodes has been impeded by limited genetic tractability, inconsistent growthin vitro, variable cryopreservation, and low mating efficiency. We obtained the recently describedSteinernema hermaphroditumstrain CS34 and optimized itsin vitrogrowth, with a rapid generation time on a lawn of its native symbiotic bacteriaXenorhabdus griffiniae. We developed a simple and efficient cryopreservation method. Previously,S. hermaphroditumisolated from insect hosts was described as first-generation hermaphroditic and second-generation gonochoristic. We discovered that CS34, when grownin vitro,produced consecutive generations of autonomously reproducing hermaphrodites accompanied by rare males. We performed mutagenesis screens inS. hermaphroditumthat produced mutant lines with visible and heritable phenotypes. Genetic analysis of the mutants demonstrated that this species reproduces by self-fertilization rather than parthenogenesis and that its sex is determined chromosomally. Genetic mapping has thus far identified markers on the X chromosome and three of four autosomes. We report thatS. hermaphroditumCS34 is the first consistently hermaphroditic entomopathogenic nematode and is suitable for genetic model development to study naturally occurring mutualistic symbiosis and insect parasitism.

Published

2021

4. The entomopathogenic nematode Steinernema hermaphroditum is a self-fertilizing hermaphrodite and a genetically tractable system for the study of parasitic and mutualistic symbiosis.

Author

Mengyi Cao, Schwartz, Hillel T., Chieh-Hsiang Tan, and Sternberg, Paul W.

Subjects

*INSECT microbiology, *GUT microbiome, *IN vitro studies, *BIOLOGICAL models, *CHROMOSOMES, *NEMATODES, *GENETICS, *PARASITOLOGY, *GENETIC mutation, *IN vivo studies, *CONCEPTION, *PHENOMENOLOGICAL biology, *ANIMAL experimentation, *SEX chromosomes, *GENETIC testing, *ENTEROBACTERIACEAE, *GENETIC markers, *DESCRIPTIVE statistics, *PARASITES, *CRYOPRESERVATION of organs, tissues, etc., *PHENOTYPES

Abstract

Entomopathogenic nematodes (EPNs), including Heterorhabditis and Steinernema, are parasitic to insects and contain mutualistically symbiotic bacteria in their intestines (Photorhabdus and Xenorhabdus, respectively) and therefore offer opportunities to study both mutualistic and parasitic symbiosis. The establishment of genetic tools in EPNs has been impeded by limited genetic tractability, inconsistent growth in vitro, variable cryopreservation, and low mating efficiency. We obtained the recently described Steinernema hermaphroditum strain CS34 and optimized its in vitro growth, with a rapid generation time on a lawn of its native symbiotic bacteria Xenorhabdus griffiniae. We developed a simple and efficient cryopreservation method. Previously, S. hermaphroditum isolated from insect hosts was described as producing hermaphrodites in the first generation. We discovered that CS34, when grown in vitro, produced consecutive generations of autonomously reproducing hermaphrodites accompanied by rare males. We performed mutagenesis screens in S. hermaphroditum that produced mutant lines with visible and heritable phenotypes. Genetic analysis of the mutants demonstrated that this species reproduces by self-fertilization rather than parthenogenesis and that its sex is determined chromosomally. Genetic mapping has thus far identified markers on the X chromosome and three of four autosomes. We report that S. hermaphroditum CS34 is the first consistently hermaphroditic EPN and is suitable for genetic model development to study naturally occurring mutualistic symbiosis and insect parasitism. [ABSTRACT FROM AUTHOR]

Published

2022